Antenna cavity structure for integrated patch antenna in integrated fan-out packaging

ABSTRACT

An integrated fan-out package having a top-side redistribution wiring structure, a back-side redistribution wiring layer, a ground plane provided in the back-side redistribution wiring layer, and a molding compound layer having a thickness and provided between the back-side redistribution wiring layer and the top-side redistribution wiring structure is disclosed. The package has an RF IC die embedded within the molding compound layer and one or more integrated patch antenna structure provided in the top-side redistribution wiring structure. The one or more integrated patch antenna structure is coupled to the RF IC die and an antenna cavity is provided within the molding compound layer under each of the one or more integrated patch antenna.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuation-in-part of co-pending U.S. patent applicationSer. No. 13/481,974, filed on May 29, 2012, which is incorporated byreference herein in its entirety.

FIELD

The present disclosure generally relates to a bead element employed inintegrated circuit packaging.

BACKGROUND

Low Temperature Co-Fired Ceramic (LTCC) and printed circuit board (PCB)substrates can be used for integration of mm-wave antennas with RFintegrated circuits (ICs) in high frequency applications but thosepackages have power consumption issues resulting from interconnectlosses from chip to antenna through solder bumps or balls. Therefore,improved antenna structures integrated into packaging is desired.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view illustration of a portion of a 2.5D/3DIC package in which one or more of the metal wiring bead of the presentdisclosure can be incorporated according to some embodiments.

FIG. 2 is an illustration of an example of a 2.5D IC package in whichone or more of the metal wiring bead according to some embodiments ofthe present disclosure can be incorporated.

FIG. 3 shows a one-layer metal wiring bead according to someembodiments.

FIG. 4 shows a one-layer metal wiring bead according to some embodiments

FIGS. 5A and 5B show two-layer metal wiring beads embodiments accordingto some embodiments.

FIGS. 6A and 6B show a two-layer metal wiring bead according to someembodiments.

FIGS. 7A and 7B show a two-layer metal wiring bead according to someembodiments.

FIG. 8 shows a three-layer metal wiring bead according to someembodiments.

FIG. 9 shows another three-layer metal wiring bead according to someembodiments.

FIG. 10 is a flow chart for a method for providing the metal wiring beadaccording to some embodiments.

FIG. 11 shows plots of R, XL, Z performance values from a simulation ofa metal wiring bead according to some embodiments of the presentdisclosure.

FIGS. 12A and 12B illustrate the relationship between the parameters Z,R, and X_(L) (impedance, resistance, and reactance) according to someembodiments.

FIG. 13 is a cross-sectional view of an exemplary InFO package accordingto some embodiments of the present disclosure, where the cross-sectionis taken through the section line A-A shown in FIG. 14.

FIG. 14 is an illustration of a top-down view of the InFO packageshowing an arrangement of patch antennas according to some embodimentsof the present disclosure.

FIG. 15 is an illustration of a top-down view of one of the patchantenna from FIG. 14 according to some embodiments.

FIG. 16 is a plot of the S11 parameter, the reflection coefficient, ofthe patch antenna structure of FIG. 15 according to some embodiments.

FIGS. 17 through 31 show cross-sectional views of intermediate stages inthe manufacturing of an InFO package in accordance with some exemplaryembodiments.

FIG. 32A is an illustration of an antenna cavity formed by a singlesolid wall structure according to some embodiments.

FIG. 32B is an illustration of an antenna cavity formed by two or morecontinuous solid segments according to some embodiments.

FIG. 32C is an illustration of an antenna cavity formed by a pluralityof through-insulator vias (TIVs) according to some embodiments.

FIGS. 33A-33B show a flow chart of the method of manufacturing the InFOpackage in accordance with some embodiments.

All drawings are schematic and are not to scale.

DETAILED DESCRIPTION

This description of the exemplary embodiments is intended to be read inconnection with the accompanying drawings, which are to be consideredpart of the entire written description. In the description, relativeterms such as “lower,” “upper,” “horizontal,” “vertical,”, “above,”“below,” “up,” “down,” “top” and “bottom” as well as derivative thereof(e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should beconstrued to refer to the orientation as then described or as shown inthe drawing under discussion. These relative terms are for convenienceof description and do not require that the apparatus be constructed oroperated in a particular orientation. Terms concerning attachments,coupling and the like, such as “connected” and “interconnected,” referto a relationship wherein structures are secured or attached to oneanother either directly or indirectly through intervening structures, aswell as both movable or rigid attachments or relationships, unlessexpressly described otherwise.

Some embodiments of the present disclosure relate to an impedanceelement, in particular, relates to an element which is used as a beadfilter or a noise filter to eliminate power noise and suppresselectromagnetic interference in integrated circuit (IC) devices.

Some embodiments of this disclosure include a multilayer interposerstructure for 2.5D/3D applications that eliminates different power noiseand suppress electromagnetic interference. Integrated fan-out (InFO)packages can be integrated with antenna structures such as patchantennas that are coupled to an RF IC die through a feed structure thatis directly connected to the RF IC die. For example, one or more antennacan be integrated with the RF IC die through an integrated fan-outredistribution structures comprising a metallization layer (e.g. aredistribution layer) coupled to a package molding compound with the RFIC die embedded therein. As the advancing RF applications requireincreasingly higher frequency RF transceiver capabilities, improved InFOpackages can meet higher frequency RF transceiver specifications.

Disclosed herein is a method for eliminating different power noise andsuppressing electromagnetic interference (EMI) in 2.5D/3D integratedcircuit (IC) packages used in communication system applications.According to an embodiment, one or more convoluted metal wiring beadshaving a convoluted shape are incorporated into the wiring structures ofthe multilayer interposer of a 2.5D/3D IC package. The convoluted metalwiring bead can be incorporated into the power lines in the IC packageand function as a bead filter or a noise filter to eliminate power linenoise. The metal wiring bead is configured to provide an appropriateimpedance to meet the power noise reduction requirement of a particularIC package's requirement. Unlike many conventional impedance elementsthat are implemented as ferrite beads or discrete surface-mount devicessuch as ferromagnetic insulation chips, incorporating the impedanceelement into the multilayer interposer structure provides more compactsolution and lower cost.

FIG. 1 is a cross-sectional view illustration of a portion of a 2.5D/3DIC package 100 in which one or more of the metal wiring bead of thepresent disclosure can be incorporated. The IC package 100 comprises anIC device 110 and an interposer 120 attached to the IC device.Generally, the IC device 110 can be encapsulated with a molding compound130.

The interposer 120 comprises a multiple layers of wiring structures. Inthis example interposer 120, the multiple layers of wiring structurescomprise a plurality of wiring layers 122, 124, and 126 and via layers121, 123 and 125. The wiring layers 122, 124, and 126 each comprisesvarious wiring structures formed from conductor materials M1, M2, M3,corresponding to the wiring layers 122, 124, 126 respectively, disposedin a dielectric material. The via layers 121, 123 and 125 each comprisesa plurality of vias generally referred to herein as V1, V2, V3,respectively, disposed in a non-ferrite polymeric dielectric material.The vias provide the electrical connection between the wiring layers.The vias V1 in the first via layer 121 provide the electrical connectionbetween the wiring structures of the first wiring layer 122 and the ICdevice 110. Generally, the conductor materials M1, M2, M3 arecopper-based metal and the dielectric material is one or more types ofpolymers. The conductor materials M1, M2, and M3 generally are the samematerials but they can be different.

According to an embodiment of the present disclosure, the metal wiringbead is provided in the interposer 120 of the IC package 100. The metalwiring bead can comprise a single layer pattern, a two-layer pattern ora three-layer pattern and can be formed in one or more of the pluralityof metal wiring layers 122, 124, and 126.

FIG. 2 is a schematic illustration of an example of a 2.5D IC package200 in which one or more of the metal wiring bead of the presentdisclosure can be incorporated. The IC package 200 comprises aninterposer 220 to which one or more IC devices 201, 202, and 203 areattached on one side and one or more IC devices 204 and 205 are attachedon the second side. One or more of the metal wiring bead of the presentdisclosure can be incorporated in the interposer 220.

FIG. 3 shows a one-layer embodiment of a metal wiring bead A accordingto an aspect of the present disclosure. The metal wiring bead A has aconvoluted wiring pattern that is formed in one of the three wiringlayers 122, 124 or 126 from the corresponding M1, M2 or M3 conductingmaterial. The convoluted wiring pattern of the metal wiring bead A has aserpentine-like portion A1 that begins at first terminal segment A2 andends at a second terminal segment A3. The serpentine-like portion A1 isa wiring trace of the conductor material provided in a meanderingserpentine-like pattern. The two terminal segments A2 and A3 provideelectrical connection to the functional power lines in the IC package.The term “serpentine-like” is used to describe the generally windingshape represented by the portion A1 where the metal wiring is windingback and forth similar to the shape formed by the body of a movingserpent.

FIG. 4 shows another one-layer embodiment of a metal wiring bead B. Themetal wiring bead B has a convoluted wiring pattern that is formed inone of the three wiring layers 122, 124 or 126 from the correspondingM1, M2 or M3 conducting material. Unlike the metal wiring bead A shownin FIG. 3, the convoluted wiring pattern of the metal wiring bead B hasa meandering loop portion B1 that begins at a first terminal segment B2,follows a square or quadrilateral outline and loops back towards thefirst terminal segment and ends at a second terminal segment B3. Theconductive line tracing in the meandering loop portion B1 meanders inright angles, but the meandering pattern of the conductive line tracecan be in any shape. The two terminal segments B2 and B3 are connectedto the functional power lines in the IC package.

FIG. 5 shows two-layer metal wiring bead embodiments C and CC. The metalwiring bead C has a convoluted wiring pattern that has two convolutedsegments C1 and C2 formed from the M1 conducting material in the firstwiring layer 122 that are electrically connected in series by theconnecting segment C3 that is formed from the M2 metal in the secondmetal wiring layer 124. Two terminal segments C4 and C5 provide theelectrical connection to the functional power lines for the IC package.The terminal segments C4 and C5 are also formed from the M2 conductingmaterial in the second metal wiring layer 124. Corresponding viastructures (not shown) in the via layer 123 connects the convolutedsegments C1 and C2 to the segments C3, C4 and C5.

The metal wiring bead CC has a convoluted wiring pattern that has twoconvoluted segments CC1 and CC2 formed from the M2 conducting materialin the second wiring layer 124 that are connected in series by theconnecting segment CC3 that is formed from the M1 conducting material inthe first metal wiring layer 121. Two terminal segments CC4 and CC5provide the electrical connection to the functional power lines for theIC package. The terminal segments CC4 and CC5 are also formed from theM1 conducting material in the first metal wiring layer 122.Corresponding via structures (not shown) in the via layer 123 connectsthe convoluted segments CC1 and CC2 to the segments CC3, CC4 and CC5.Because FIG. 4 is a plan view of the metal wiring beads C and CC, thevia structures connecting the M1 conducting material structures with theM2 conducting material structures would be oriented orthogonal to theplane of the drawings and hidden between the connecting parts of the M1and M2 conducting material structures.

FIGS. 6A and 6B show another two-layer metal wiring bead embodiment D.The metal wiring bead D has a convoluted wiring pattern having aquadrilateral outline that has a first set of a plurality of linesegments D1 formed from the M1 conducting material in the first wiringlayer 122 and a second set of a plurality of line segments D2 formedfrom the M2 conducting material in the second wiring layer 124. Aplurality of vias D-via in the via layer 123 provide the electricalconnection between the first set of line segments D1 and the second setof line segments D2 and form a serpentine-like convoluted pattern forthe metal wiring bead D. The first set of line segments D1 and thesecond set of line segments D2 are in a staggered arrangement as shownand the vias D-via connect each of the line segments in the first set D1and the second set D2 to two line segments in the other set. Forexample, referring to FIG. 6A, the line segment 10 in the first set D1is connected to two of the line segments 31 and 32 in the second set D2by the vias 21 and 22. The same is true for the line segment 12 locatedat the corner of the square-shaped outline of the metal wiring bead D.The only difference is that the line segment 12 has a bend in the middleof the segment to form the corner section of the metal wiring bead D.The vias D-via are configured to extend not only in the Z-direction(i.e., the direction orthogonal to the plane of the wiring layers) butalso extend along the direction parallel to the plane of the wiringlayers. In the illustrated example of vias 21 and 22, they extend alongY-direction for a distance of d to make the connection between the linesegment 10 and the line segments 31 and 32. Two terminal segments D3 andD4 provide the electrical connection to the functional power lines forthe IC package. The terminal segment D3 is formed from the M1 conductingmaterial in the first wiring layer 122 and the terminal segment D4 isformed from the M2 conducting material in the second wiring layer 124.FIG. 5B shows an isometric view illustration of the metal wiring bead D.

FIGS. 7A and 7B show another two-layer metal wiring bead embodiment E.The metal wiring bead E has a convoluted wiring pattern that forms aserpentine-like that has a first set of a plurality of line segments E1formed from the M1 conducting material in the first wiring layer 122 anda second set of a plurality of line segments E2 formed from the M2conducting material in the second wiring layer 124. A plurality of viasE-via in the via layer 123 provide the electrical connection between thefirst set of line segments E1 and the second set of line segments E2 andform a serpentine-like convoluted pattern for the metal wiring bead E.The vias E-via extend at least 100 μm along the X or Y direction withinthe via layer (i.e. the directions parallel to the plane of the wiringlayers), thereby comprising a substantial portion of the total length ofthe metal wiring bead E. In one embodiment, the extended vias compriseat least 50% of the total length of the metal wiring bead E. The firstand second sets of line segments E1 and E2 have a curved configurationrather than being straight line segments. Two terminal segments E3 andE4 provide the electrical connection to the functional power lines forthe IC package.

FIG. 8 shows a three-layer metal wiring bead embodiment F according toan aspect of the present disclosure. The metal wiring bead F comprises aconvoluted wiring pattern that forms a serpentine-like structure in eachof the three wiring layers 122, 124, and 126 that are electricallyconnected in series. In the first wiring layer 122, a firstserpentine-like portion F1 is formed from the M1 conductor material. Inthe second wiring layer 124, a second serpentine-like portion F2 isformed from the M2 conductor material. In the third wiring layer 126, athird serpentine-like portion F3 is formed from the M3 conductormaterial. The electrical connection between the first serpentine-likeportion F1 and the second serpentine-like portion F2 is provided by avia F-via1 provided in the via layer 123. The electrical connectionbetween the second serpentine-like portion F2 and the thirdserpentine-like portion F3 is provided by a via F-via2 provided in thevia layer 125. Two terminal segments F4 and F5 provide the electricalconnection to the functional power lines for the IC package.

FIG. 9 shows another three-layer metal wiring bead embodiment Gaccording to another aspect of the present disclosure. The metal wiringbead G comprises a convoluted wiring pattern in each of the three wiringlayers 122, 124, and 126 that are electrically connected in series. Inthe first wiring layer 122, a first convoluted wiring pattern G1 isformed from the M1 conductor material. In the second wiring layer 124, asecond convoluted wiring pattern G2 is formed from the M2 conductormaterial. In the third wiring layer 126, a third convoluted wiringpattern G3 is formed from the M3 conductor material. The electricalconnection between the first convoluted wiring pattern G1 and the secondconvoluted wiring pattern G2 is provided by a via G-via1 provided in thevia layer 123. The electrical connection between the second convolutedwiring pattern G2 and the third convoluted wiring pattern G3 is providedby a via G-via2 provided in the via layer 125. Two terminal segments G4and G5 provide the electrical connection to the functional power linesfor the IC package. As shown, the three convoluted wiring patterns G1,G2, and G3 have different size outlines, the first convoluted wiringpattern G1 having the smallest outline and the third convoluted wiringpattern G3 having the largest so that the second and the firstconvoluted wiring patterns G2 and G1 are nested within the outline ofthe third convoluted wiring pattern G3 when viewed from the top as shownin FIG. 8. This configuration is another example that providessufficient metal length for the metal wiring bead G which will provideproper R (resistance) and XL (reactance) values for the bead.

FIG. 10 shows a flow chart of a method for providing the metal wiringbead according to an embodiment. First, based on a performancerequirement defined for a particular IC package, the necessary impedancespecification for the metal wiring bead is determined. (See block 51).This is referred to herein as the desired impedance value. Then, adetermination is made as to whether one, two or three layers of metalshould be used to make the metal wiring bead for the particular ICpackage that will produce the necessary impedance. (See block 52). Onedetermines whether one, two or three layers of metal should be useddepending on the metal wiring bead impedance value that is necessary ina given application. Next, a determination is made as to the wiringpattern (e.g. a square, circle, etc.) of the metal wiring bead for theparticular IC package that will produce the necessary impedance. (Seeblock 53). The particular wiring pattern is chosen that would providethe desired wiring bead impedance value. Before the design for the metalwiring bead is finalized and implemented into the manufacturing processfor the interposer for the IC package, a computer simulation isconducted to verify whether the specified impedance is met by thedetermined number of metal layers and the wiring pattern for the metalwiring bead. (See block 54).

If the results of the simulation shows that the desired impedance valueis not achieved by the particular metal wiring bead design parameters,then the steps identified in the blocks 52, 53 and 54 are repeated untila metal wiring bead design parameters with the desired impedance valueis achieved. If the results of the simulation shows that the desiredimpedance value is achieved by the particular metal wiring bead designparameters, the simulation is complete and the design parameters can beincorporated into the manufacturing design data for the interposer for a2.5D/3D IC package.

FIG. 11 shows plots of Z, R, and XL (impedance, resistance, andreactance) values at 102.5 MHz from a simulation of a metal wiring beadaccording to the present disclosure. The general relationship betweenthe parameters Z, R, and XL used for such simulation calculations iswell known in the art and is represented by the illustrations in FIGS.12A and 12B.

The bead element of the present disclosure can be employed in ICpackages and in particular, to a multilayer interposer structure for2.5D/3D multi-chip packaging technologies to eliminate or substantiallyreduce different power noise and suppress electromagnetic interferencein communication system applications.

Integrated fan-out (InFO) packages, also known as integrated fan-outwafer level package (InFO-WLP), have become popular in recent times. Inan InFO package, fan out wirings between input/output (I/O) pins on thedie and package I/O pins can be formed in a redistribution layer (RDL)over the die. The die is surrounded laterally by a medium, such as amolding compound, encapsulant, epoxy resin, or the like. The RDL canextend laterally beyond the perimeter of the die. The RDL layercomprises a patternable dielectric material, in which conductivepatterns and conductive vias can be formed. InFO packages can providesignificantly thinner packages with much tighter redistribution linepitches (10 μm) compared to other fan-out structures for die packagingtechnologies. InFO packages provide many advantages over packages suchas FC-BGA (flip-chip ball grid array) packaging since passive devicessuch as inductors and capacitors can be formed beyond the perimeter ofan IC die (e.g., over molding compound) for lower substrate loss andhigher electrical performance. The smaller die form factor also leads tobetter thermal performance and thus a lower operating temperature forthe same power budget. Alternatively, by taking advantage of theimproved thermal performance, faster circuit operation speed can beachieved for the same temperature profile as FC-BGA.

According to some embodiments of the present disclosure, an InFO packagehaving one or more integrated patch antenna is provided, where eachintegrated patch antenna incorporates an insulator filled antenna cavitystructure for improved antenna performance and efficiency at highfrequency applications.

The antenna cavity structure provided according to some embodiments ofthe present disclosure may improve the reflection coefficient, the S11parameter, of the integrated patch antenna in the InFO package,especially in high frequency applications that employ antenna efficiencyat frequencies of 5.8 GHz and higher. The antenna cavity structure alsohelps reduce the undesirable couplings of the antenna to the nearbycircuits, and prevent the unwanted noise from the circuits from reachingthe antenna.

The embodiments described below provide many applicable concepts thatcan be embodied in a wide variety of specific contexts. The specificembodiments discussed are illustrative, and do not limit the scope ofthe disclosure.

A description of an InFO package and a method of forming the same areprovided in accordance with some embodiments. The intermediate stages offorming the InFO package are illustrated. Throughout the various viewsand illustrative embodiments, like reference numbers are used todesignate like elements.

In some embodiments, as shown in FIG. 13, an InFO package 300 comprises:a top-side redistribution wiring structure 400; a back-sideredistribution wiring layer 500; a ground plane 510 provided in theback-side redistribution wiring layer; a molding compound layer 70having a thickness and provided between the back-side redistributionwiring layer and the top-side redistribution wiring structure; an RFintegrated circuit die 310 at least laterally embedded within themolding compound layer; one or more integrated patch antenna structure427 provided in the top-side redistribution wiring structure, whereinthe one or more integrated patch antenna structure is coupled to the RFintegrated circuit die and configured to radiate electromagneticradiation for wireless transmission or to receive electromagneticradiation for wireless reception; one or more cavity sidewall structures303A provided within the molding compound layer and in electricalcontact with the ground plane 510 and extending from the ground planethrough the thickness of the molding compound layer 70; and an antennacavity 327 provided within the molding compound layer under each of theone or more integrated patch antenna structure, wherein each of theantenna cavity is defined by a cavity sidewall structure and the groundplane and the antenna cavity is filled with the molding compound.

In some embodiments of the InFO package 300 one or more ground planestructures 510 are provided and each of the antenna cavity is defined bya cavity sidewall structure and one of the at least one or more groundplane structures.

FIG. 13 is a cross sectional view of an embodiment of an InFO package300 according to an aspect of the present disclosure. The cross-sectionis taken through the section line A-A shown in the top-down view of theInFO package illustrated in FIG. 14. InFO packages such as the InFOpackage 300 can have a plurality of integrated circuit (IC) dies. FIG.13 shows a portion of InFO package 300 containing an RF IC die 310.

The RF IC die 310 is embedded in a medium, such as a molding compound70. The bottom side of the RF IC die 310 has a back-side redistributionlayer RDL 500 (FIG. 19) that can contain one or more conductorstructures, such as conductor 510. On the top-side of the RF IC die 310,a top-side redistribution wiring structure 400 is provided. The RDLwiring patterns can include wiring patterns at least partially over theRF IC die 310 and/or wiring patterns at least partially over the moldingcompound 70 material. The top-side redistribution wiring structure 400generally comprises a plurality of redistribution layers each comprisinga plurality of conductor structures. The top-side redistribution wiringstructure 400 provides electrical connection between the RF IC die 310and the interconnection structures such as the solder bumps 600 on thetop-side of the InFO package 300. The solder bumps 600 provideelectrical interconnection to the next level packaging such as, forexample, a printed circuit board (PCB) or an interposer.

The conductor structures 510 in the back-side redistribution layer 500can also be electrically conductively connected to the interconnectionstructures such as the solder bumps 600 on the top-side of the InFOpackage 300 through the top-side redistribution wiring structure 400.The electrical connection between the conductor structures 510 in theback-side redistribution layer 500 and the top-side redistributionwiring structure 400 can be provided by one or more of through-insulatorvias (TIVs), also known as through-InFO vias, 303. The TIVs 303 areconductive metal structures that extend through the thickness of themedium (e.g., molding compound) 70.

In the illustrated example InFO package 300, the top-side redistributionwiring structure 400 comprises three top-side redistribution line (RDL)layers 410, 420, and 430. In other embodiments, different number of RDLlayers can be included. Each RDL layer comprises RDLs and vias which aremetal conductor features that provide the electrical interconnectionsthrough and within the top-side redistributon wiring structure 400. Insome embodiments, the RDL lines and vias comprise copper. In the firsttop-side RDL layer 410, first level conductors (RDL-1) 412 and firstlevel vias (RDL-1 vias) 415 provide the interconnections. In the firsttop-side RDL layer 410, a dielectric layer 413 is provided over theRDL-1 412. In the second top-side RDL layer 420, second level conductors(RDL-2) 422 and second level vias (RDL-2 vias) 425 provide theinterconnections. In the second top-side RDL layer 420, a dielectriclayer 423 is provided over the RDL-2 422. In the third top-side RDLlayer 430, which is the last RDL layer, third level conductors (RDL-3)432 and under ball metal (UBM) pads 435 provide the interconnections.The solder bumps 600 are formed on the UBM pads 435. In the thirdtop-side RDL layer 430, a dielectric layer 433 is provided over theRDL-3 432.

The InFO package 300 comprises one or more integrated patch antenna 427electrically coupled to the RF IC die 310 by a feed line 428. A patchantenna is a microstrip antenna comprising a flat rectangular sheet or“patch” of metal, mounted over a larger sheet of metal called a groundplane. In some embodiments, the patch antenna is formed in one of theRDL layers. Each integrated patch antenna 427 is provided with anantenna cavity structure 327 underneath the integrated patch antenna427. The antenna cavity structure 327 is formed by a cavity sidewall303A that is connected to a ground plane 510 which forms the bottom sideof the antenna cavity 327. In some embodiments, the cavity sidewall 303Acomprises TIVs. In other embodiments, the cavity sidewall comprises oneor more continuous elongated “slot vias”.

Generally, a patch antenna includes a radiating patch on one side of adielectric substrate which has a ground plane on the other side. Theintegrated patch antenna 427 can be provided in any shape. For example,the shape of the integrated patch antenna 427 can be provided in anyshape, e.g. a circle, an ellipse, or any desired polygonal shape such asa triangle, a square, a rectangle, a pentagon, a hexagon, an octagon,etc. However, for a given RF application for the InFO package, aparticular shape may be desirable for the integrated patch antenna 427based on the particular RF signal transmission/reception specificationsimposed by that RF application. For example, in some intendedapplications, a square shaped patch antenna may be advantageous comparedto other shapes.

The ground plane 510 is a conductor structure in the back-sideredistribution metal layer 500 that is electrically grounded when theInFO package 300 is installed into its intended application environment.For example, in some embodiments, the ground plane 510 is electricallyconductively connected to solder bumps 600A by way of the TIV 303 andthe corresponding top-side redistribution wiring structures, RDL-1 412,RDL-1 via 415, RDL-2 422, RDL-2 via 425, RDL-3 432, and UBM pad 435. Theground plane 510 can be formed as a solid metal planar structure or anyother suitable structure. For example, in some embodiments, the groundplane 510 can be formed as a mesh or a set of electrically conductivelyconnected parallel lines.

The antenna cavity sidewalls 303A are formed from a conductive material.In the example InFO package 300, the cavity sidewalls 303A are formedfrom the same conductive metal as the TIVs 303. When the InFO package300 is installed into its intended application environment, the solderbumps 600A are connected to electrical ground and, in turn, the groundplane 510 and the cavity sidewall 303A become grounded.

In some embodiments, each of the cavity sidewalls 303A can be formed asa single continuous solid wall structure connected on the bottom side bythe ground plane 510 enclosing an area underneath the integrated patchantenna 427. FIG. 32A provides a schematic illustration of this example.In other embodiments, each of the cavity sidewalls 303A can be formed oftwo or more continuous solid segments that together enclose an areaunderneath the integrated patch antenna 427. FIG. 32B provides aschematic illustration of this example. On each side of the cavitysidewall structure, a continuous solid segment extends an entiredistance from one corner of the cavity sidewall structure to an adjacentcorner of the cavity sidewall structure. The two or more solid segmentscan be separated by a spacing from about 10 μm. In other embodiments,the cavity sidewalls 303A can be formed from a plurality of TIVs thattogether define the perimeter of the antenna cavity 327. The spacingbetween adjacent TIVs forming the cavity sidewalls is selected based onthe wavelengths of the signals the antenna is intended to transmitduring operation. FIG. 32C provides a schematic illustration of thisexample. In some embodiments, the spacing between the TIVs are in arange from about 10 μm wide.

The cavity sidewalls 303A and the ground plane 510 can be formed to haveany shape for its perimeter outline. In some embodiments, the cavitysidewalls 303A and the ground plane 510 are configured to have perimeteroutline shapes that match the perimeter outline of the integrated patchantenna 427. Thus, if the integrated patch antenna 427 is square shaped,the cavity sidewalls 303A and the ground plane 510 will also be providedto have a square shaped outline that is of the appropriate size to matchthe size of the integrated patch antenna 427.

FIG. 14 a schematic illustration of a top-down view of the InFO package300. The RF IC die 310 is shown in the center that is connected to fourpatch antennas 427. Antenna feed lines 428 connect the patch antennas427 to the RF IC die 310. The ground plane 510 positioned below thepatch antennas 427 can be seen. The antenna cavities 327 and the cavitysidewalls 303A are underneath the patch antennas 427 between the patchantennas 427 and the ground plane 510 and thus are not visible in thistop-down view.

FIG. 15 is a schematic illustration of a top-down view of one of thepatch antennas from FIG. 14. The insulator filled antenna cavity 327defined by the cavity sidewall structures 303A and the ground plane 510is shown. In this example, a plurality of TIV structures form the cavitysidewall structure 303A. In some embodiments, sidewall structurescomprising TIV's are conductively connected to the ground plane 510, butthe top ends of the TIV structures do not contact the patch antennal427.

FIG. 16 is a plot of the S11 parameter, the reflection coefficient, ofthe patch antenna 427 structure having the insulator filled antennacavity 327 shown in FIG. 15. The S11 values were generated from asimulation of the patch antenna 427 structure shown in FIG. 15. The plotshows that the antenna efficiently radiates between about 11.5 GHz and12.8 GHz. Therefore such antenna would be suitable for meeting thespecifications of the future 4^(th) generation (5.8 GHz) and 5^(th)generation (38 GHz) high frequency RF transceivers in mobilecommunication applications.

The antenna cavity 327 can be filled with any one of a number ofinsulator materials compatible with InFO package processing and notlimited by the insulator's dielectric constant. Thus, the patch antennastructure of the present disclosure can be robustly implemented in aInFO package process using high-k or low-k materials.

As described below, one of the benefits of the integrated patch antenna427 having the associated antenna insulator cavity 327 according to thisdisclosure is that these structures can be formed using the existingInFO package manufacturing process flow without interrupting the processflow or requiring retooling of the process equipment. The InFo packagemanufacturing process can utilize 12 inch wafer fabrication processingtools, for example. Therefore, the InFO package having the integratedpatch antenna 427 and the associated antenna insulator cavity 327provides a low-cost solution for meeting more demanding antennaefficiency specifications of the future (e.g., 4^(th) and 5^(th))generation high frequency RF transceiver applications.

Referring to FIGS. 17 through 31, an example of a process of forming theInFO package 300 is described. FIGS. 17 through 31 show cross-sectionalviews of intermediate stages in the manufacturing of an InFO package 300structure in accordance with some exemplary embodiments. Referring toFIG. 17, a carrier 10 is provided, and an adhesive layer 20 is depositedon the carrier 10. The carrier 10 can be a blank glass carrier, a blankceramic carrier, or the like. The adhesive layer 20 can be formed of anadhesive such as a ultra-violet (UV) glue, Light-to-Heat Conversion(LTHC) glue, or the like, although other types of adhesive may be used.

Referring to FIG. 18, a back-side buffer layer 30 is formed over theadhesive layer 20. The back-side buffer layer 30 is a dielectric layer,which can comprise a polymer. The polymer can be, for example,polyimide, PolyBenzOxazole (PBO), BenzoCycloButene (BCB), AjinomotoBuildup Film (ABF), Solder Resist film (SR), or the like. The back-sidebuffer layer 30 is a planar layer having a uniform thickness, whereinthe thickness may be greater than about and may be from about 2 μm toabout 40 μm. The top and the bottom surfaces of the back-side bufferlayer 30 are also planar. The back-side buffer layer 30 will act as thefinal protective insulator for the finished InFO package 300.

Next, one or more of the ground plane structures 510 are formed in theback-side redistribution metal layer 500. The back-side redistributionmetal layer 500 is formed of conductor metal such as Cu or Cu-basedalloy and the ground plane structures 510 can be selectively depositedon the back-side buffer layer 30 by electroplating through a photoresistmask layer which is then removed. The intermediate photoresist maskformation and removal are not illustrated. In this example, the groundplane structures 510 are formed by electroplated Cu that are about 7 μmthick. The Cu was plated over a Ti/Cu (1000/5000 Å thick) seed layer.

Referring to FIG. 20, a coating of photoresist 40 is applied over theground plane structure 510 and the exposed portions of the back-sidebuffer layer 30. Then, the photoresist 40 is patterned to form openingsor recesses 45 in the photoresist 40. Such patterning is done by aphotolithography process. The recesses 45 expose some portions of theback-side redistribution metal layer 500. The recesses 45 will besubsequently filled with conductive metal to make the TIVs 303 andcavity sidewalls 303A. Thus, the shape of the recesses 45 will depend onwhether recesses are for the TIVs 303 or the cavity sidewalls 303A. Forexample, if a particular recess is intended for forming a TIV 303, thatrecess 45 will be a hole appropriately shaped to form the TIV 303. TIVscan be cylindrical in form or pillars having different polygonalcross-sectional shape. If a particular recess is intended for forming acavity sidewall 303A, that recess 45 can be a hole or a trench dependingon whether the cavity sidewall 303A is formed from a plurality of TIVs,two or more solid segments, or a single solid wall-like structure. Therecesses 45 will have a depth that can form the TIVs and the cavitysidewalls 303A with a desired height. In typical InFO packages, therecesses 45 will be sufficiently deep to form TIVs 303 having a heightof about 120-250 μm. The height of the TIVs 303 is determined by thethickness of the subsequently placed IC dies, such as the RF IC die 310in the example InFO package 300.

Referring to FIG. 21, a thin seed layer of Ti/Cu (1000/5000 Å thick)(not shown) is formed on the structure of FIG. 20 in preparation forelectroplating deposition of the TIVs 303 and the cavity sidewalls 303Aso that the seed layer is covering the surfaces of the photoresist 40and the exposed back-side redistribution metal layer 500, such as theground plane structure 510 at the bottom of the recesses 45. Next, themetal features such as the TIVs 303 and the cavity sidewalls 303A areformed by filling the recesses 45 in the photoresist 40 with conductivemetal 60 by plating, which may be electro plating or electro-lessplating, on the seed layer 50. The conductive metal 60 may comprise suchconductive metals as copper, aluminum, tungsten, nickel, or alloysthereof.

Next, referring to FIG. 22, any excess portion of the conductive metal60 is removed by a process such as chemical mechanical polishing (CMP),exposing the tops of the recesses 45 and the photoresist layer 40. Therecesses are now filled with the conductive metal 60.

Next, the photoresist 40 is removed and the resulting structure is shownin FIG. 23. The recesses 45 in the photoresist 40 now form the TIVs 303and the cavity sidewalls 303A structures.

FIG. 24 illustrates the placement of the RF IC die 310 on the back-sidebuffer layer 30. IC dies such as the RF IC die 30 can be adhered to theback-side buffer layer 30 using a die-attach-film (DAF) 36. The RF ICdie 310 includes semiconductor substrate 35 (a silicon substrate, forexample) whose back surface is in contact with the DAF 36. The RF IC die310 includes metal pillars 315 (such as copper posts) that are formed asthe top portions of the RF IC die 310 that electrically connects the RFIC die 310 to other conductive devices and interconnect structures inthe InFO package 300. A dielectric layer 316 is formed at the topsurface of the RF IC die 310 filling the spaces between the metalpillars 315, with the metal pillars 315 having at least their lowerportions in the dielectric layer 316. In some embodiments, the topsurface of the dielectric layer 316 can be level with the top surfacesof the metal pillars 315, as shown in the RF IC die 310.

Referring to FIG. 25, a molding compound 70 is applied over the RF ICdie 310, the TIVs 303, and the cavity sidewalls 303A and cured. Themolding compound 70 fills the gaps between the RF IC die 310, the TIVs303, and the cavity sidewalls 303A, and may be in contact with anyexposed portions of the back-side buffer layer 30 and the ground planestructure 510. The molding compound 70 may include a molding underfill,an epoxy, or a resin. Some suitable molding compounds can be liquidepoxys, such as liquid epoxy containing fine granular silica, liquidglass (SiO₂) (spin on glass) or ceramics. Molding compounds such as theliquid epoxy can be applied as a coating, similar to photoresists, thenlow temperature (about 180° C.) cured and hardened. In some embodiments,the molding compound has a dielectric constant k of 2.8-3.0. Otherembodiments include high-k or low-k molding materials. The moldingcompound 70 provided in sufficient amount to embed the RF IC die 310,the TIVs 303, and the cavity sidewalls 303A. At this stage, the topsurface of the molding compound 70 is higher than the top ends of themetal pillars 315 on the RF IC die 310, the TIVs 303, and the cavitysidewalls 303A.

Next, a grinding step is performed to thin the molding compound 70 untilthe tops of the metal pillars 315, the TIVs 303, and the cavitysidewalls 303A are exposed. The grinding can be accomplished by CMP. Theresulting interim substrate structure 300-I is shown in FIG. 26. Thegrinding leaves the top ends of the metal features, the metal pillars315, the TIVs 303, and the cavity sidewalls 303A, to be substantiallylevel (coplanar) along the top surface 72. The grinding step can leavebehind some metal residue such as metal particles on the top surface 72.Accordingly, after the grinding step, a cleaning may be performed, forexample, through a wet etching, to remove the metal residue. The cavitysidewalls 303A and their associated ground plane 510 define the antennacavity 327. In the interim substrate structure 300-I, the moldingcompound at least laterally encapsulates the RF IC die 310 between afirst surface 71 of the molding compound and a second surface 72 of themolding compound. The one or more TIVs 303 and the one or more cavitysidewalls 303A are in the molding compound and extend from the groundplane structure 510 to the second surface 72 of the molding compound,wherein the cavity sidewalls and their associated ground plane structure510 define one or more antenna cavities 327.

Next, referring to FIG. 27, the first level conductor RDL-1 412 isformed by first forming a first top-side RDL layer 410. Forming thefirst top-side RDL layer 410 comprises depositing a layer of conductormetal (e.g. copper) 80 over the top surface 70A by plating, which may beelectro plating or electro-less plating. In order to enable the electroplating, a very thin seed layer of Ti/Cu (1000/5000 Å thick) (not shown)is first deposited on the top surface 70A. Next, the layer of conductormetal 80 is patterned and etched, leaving behind the first levelconductor RDL-1 412 structures over the TIVs 303 and the metal pillars315 of the RF IC die 310. Then, a dielectric insulation layer (e.g. PBO)81 is applied over the resulting structure. The dielectric insulationlayer 81 is about 4.5 μm thick. This structure is shown in FIG. 28.

Forming the top-side redistribution wiring structure 400 is continued bypatterning the dielectric insulation layer 81 and forming openings forvias which are then filled with conductor metal (e.g. copper) to formthe RDL-1 vias 415 and completing the first top-side RDL layer 410. Thetop surface of the first top-side RDL layer 410 is ground and polished.Then the second top-side RDL layer 420 is formed on the first top-sideRDL layer 410. In order to form the second top-side RDL layer 420, alayer of conductor metal (e.g. copper) is deposited over the firsttop-side RDL layer 410 then patterned and etched, leaving behind thesecond level conductor RDL-2 422 structures over the first top-side RDLlayer 410. A dielectric insulation layer (e.g. PBO) 83 is then appliedover the resulting structure. This structure is shown in FIG. 30.

As shown in FIG. 29 and as mentioned above, some of the second levelconductor RDL-2 422 structures include the one or more patch antennastructures 427 according to the present disclosure. The patch antennastructures 427 are formed to be positioned over the antenna cavity 327defined by the cavity sidewalls 303A and the ground plane 510.

Forming the top-side redistribution wiring structure 400 is continued bypatterning the dielectric insulation layer 83 and forming openings forvias which are then filled with conductor metal (e.g. copper) to formthe RDL-2 vias 425 and completing the second top-side RDL layer 420. Thetop surface of the second top-side RDL layer 420 is ground and polished.Then the third top-side RDL layer 430 is formed on the second top-sideRDL layer 420. In order to form the third top-side RDL layer 430, alayer of conductor metal (e.g. copper) is deposited over the secondtop-side RDL layer 420 then patterned and etched, leaving behind thethird level conductor RDL-3 432 structures over the second top-side RDLlayer 420. A dielectric insulation layer (e.g. PBO) 85 is then appliedover the resulting structure. This structure is shown in FIG. 30.

Forming the top-side redistribution wiring structure 400 is continued bypatterning the dielectric insulation layer 85 and forming openings forunder ball metal (UBM) pads 435 which are then filled with conductormetal (e.g. copper) to form the UBM pads 435 and completing the thirdtop-side RDL layer 430. This structure is shown in FIG. 31.

FIG. 31 further shows the formation of the next level electricalinterconnection structures 600 in accordance with some embodiments. Inthis embodiment, the electrical interconnection structures 600 aresolder bumps attached to the exposed portions of the UBM pads 435. Thesolder bumps 600 can be formed by placing solder balls on the UBM pads435 and then reflowing the solder balls. In alternative embodiments, theformation of the solder bumps 600 includes performing a plating step toform solder regions over the UBM pads 435, and then reflowing the solderregions. In other embodiments the electrical interconnection structures600 can be metal pillars, or metal pillars and solder caps, which mayalso be formed through plating.

The RDL-1 412, RDL-1 vias 415, RDL-2 422, RDL-2 vias 425, RDL-3 432, andUBM pads 435 can comprise a metal or a metal alloy including aluminum,copper, tungsten, and/or alloys thereof.

In some embodiments, the dielectric insulation layers 81, 83, and 85 maycomprise a polymer such as polyimide, benzocyclobutene (BCB),polybenzoxazole (PBO), or the like. Alternatively, the dielectric layers81, 83, and 85 may include non-organic dielectric materials such assilicon oxide, silicon nitride, silicon carbide, silicon oxynitride, orthe like.

Next, the InFO package 300 is debonded from the carrier 10. The adhesivelayer 20 is also cleaned from the InFO package 300. The resulting finalInFO package 300 is shown in FIG. 13.

FIGS. 33A-33B show a flow chart 700 of a method of manufacturing theInFO package 300 in accordance with some embodiments. Referring to block702, the adhesive layer 20 is deposited on the carrier 10. Next, theback-side buffer layer 30 is formed over the adhesive layer 20. (Seeblock 704). Next, one or more of the ground plane structures 510 areformed on the back-side buffer layer. (See block 706). Next, a coatingof photoresist 40 is applied over the ground plane structure 510 and theexposed portions of the back-side buffer layer 30 and patterned to formopenings or recesses 45 in the photoresist 40. (See block 708). Next,one or more TIVs 303 and one or more cavity sidewalls 303A are formed byfilling the recesses 45 with conductive metal 60. (See block 710). Next,the excess portion of the conductive metal 60 is removed and planarized,exposing the tops of the recesses 45, which are now filled with theconductive metal 60, and the photoresist layer 40. (See block 712).Next, the photoresist 40 is removed leaving behind the TIVs 303 and thecavity sidewalls 303A structures. (See block 714). Next, the RF IC die310 is placed on the back-side buffer layer 30. (See block 716).

Next, an encapsulating medium, such as a molding compound is flowed overthe RF IC die 310, TIVs 303 and ground plane structures 510. An interimsubstrate structure 300-I that comprises the RF IC die, the one or moreTIVs, the one or more cavity sidewalls, and a molding compound 70 isformed by laterally encapsulating the RF IC die, the one or more TIVs,the one or more cavity sidewalls, with the molding compound, wherein thecavity sidewalls and their associated ground plane structure define oneor more antenna cavities. (See block 717). In the interim substratestructure 300-I, the molding compound at least laterally encapsulatesthe RF IC die 310 between a first surface 71 of the molding compound anda second surface 72 of the molding compound. The one or more TIVs 303and the one or more cavity sidewalls 303A are in the molding compoundand extend from the ground plane structure 510 to the second surface 72of the molding compound, wherein the cavity sidewalls and theirassociated ground plane structure 510 define one or more antennacavities 327.

To form the interim substrate structure 300-I, a molding compound 70 isapplied over the RF IC die 310, the TIVs 303, and the cavity sidewalls303A, filling the gaps between the RF IC die 310, the TIVs 303, and thecavity sidewalls 303A, and cured. (See block 718). Next, the moldingcompound 70 is ground down until the tops of the metal pillars 315, theTIVs 303, and the cavity sidewalls 303A are exposed, thus forming theinterim substrate structure 300-I. (See block 720). At this point, thecavity sidewalls 303A and their associated ground plane 510 define theantenna cavities 327 according to the present disclosure.

Next, a top-side RDL wiring structure 400 that includes one or moreintegrated patch antenna structure 427 is formed. (See block 721). Asmentioned above, the one or more integrated patch antenna structure iscoupled to the RF IC die 310 and each of the one or more integratedpatch antenna structure is positioned over one of the antenna cavities327. The forming of the top-side RDL wiring structure 400 comprisesforming the first top-side RDL layer 410 on the ground surface of theinterim substrate structure, wherein the first top-side RDL layer 410including the first level conductor RDL-1 412 structures over the TIVs303 and the metal pillars 315 of the RF IC die 310. (See block 722).Next, the second top-side RDL layer 420 is formed on the first top-sideRDL layer 410, wherein the second top-side RDL layer 420 includes thesecond level conductor RDL-2 422 structures over the first top-side RDLlayer 410, the second level conductor RDL-2 422 structures including theone or more patch antenna structures 427 that are positioned over theantenna cavity 327. (See block 724). Next, the third top-side RDL layer430 is formed on the second top-side RDL layer 420, wherein the thirdtop-side RDL layer 430 includes the third level conductor RDL-3 432structures including the UBM pads 435. (See block 726). Next, the nextlevel electrical interconnection structures 600 are formed on the UBMpads 435. (See block 728). Next, the carrier 10 is removed, thus formingthe InFO package 300. (See block 730).

The InFO process is robust and, thus, the thickness of the InFO package300 can be fabricated to be within a wide range of thickness. Forexample, the InFO package can be fabricated to have a thickness that isanywhere from 200 μm to 2.0 mm for the 5^(th) generation high frequencyRF transceiver application.

Although the subject matter has been described in terms of exemplaryembodiments, it is not limited thereto. Rather, the appended claimsshould be construed broadly, to include other variants and embodiments,which may be made by those skilled in the art.

What is claimed is:
 1. An integrated fan-out package comprising: atop-side redistribution wiring structure; a back-side redistributionwiring layer having a ground plane therein; a molding compound layerhaving a thickness and provided between the back-side redistributionwiring layer and the top-side redistribution wiring structure; a radiofrequency (RF) integrated circuit (IC) die at least laterally embeddedwithin the molding compound layer; one or more integrated patch antennastructure in the top-side redistribution wiring structure, wherein theone or more integrated patch antenna structure is coupled to the RF ICdie; an antenna cavity within the molding compound layer under each ofthe one or more integrated patch antenna structure, wherein each of theantenna cavity is defined by a cavity sidewall structure and the groundplane, wherein the cavity sidewall structure is provided within themolding compound layer and in electrical contact with the ground planeand extending from the ground plane through the thickness of the moldingcompound layer.
 2. The integrated fan-out package of claim 1, whereinthe cavity sidewall structure is a single solid wall structureconductively connected to the ground plane.
 3. The integrated fan-outpackage of claim 1, wherein the cavity sidewall structure comprises twoor more continuous segments that are conductively connected to theground plane, each continuous segment extending from a corner of thecavity sidewall structure to an adjacent corner of the cavity sidewallstructure.
 4. The integrated fan-out package of claim 1, wherein thecavity sidewall structure comprises a plurality of through-InFO viasthat are conductively connected to the ground plane.
 5. The integratedfan-out package of claim 1, wherein the molding compound is one of anepoxy, a polymer, a spin-on-glass, or a ceramic.
 6. The integratedfan-out package of claim 1, wherein the top-side redistribution wiringstructure comprises at least three levels of redistribution wiringlayers and the one or more integrated patch antenna structure isprovided in a middle one of the at least three levels of redistributionwiring layers.
 7. The integrated fan-out package of claim 1, wherein theground plane is a solid metal planar structure.
 8. The integratedfan-out package of claim 1, wherein the ground plane is formed of a meshor a set of electrically conductively connected parallel lines.
 9. Theintegrated fan-out package of claim 1, wherein the one or moreintegrated patch antenna structure comprises a radiating patch on oneside of a dielectric substrate which has a ground plane on the otherside.
 10. The integrated fan-out package of claim 1, wherein each cavitysidewall structure is configured to have a perimeter outline shape thatmatches the corresponding one or more integrated patch antennastructure's perimeter outline.
 11. An integrated fan-out packagecomprising: a top-side redistribution wiring structure; a back-sideredistribution wiring layer having one or more ground planes therein; amolding compound layer having a thickness and provided between theback-side redistribution wiring layer and the top-side redistributionwiring structure; a radio frequency (RF) integrated circuit (IC) die atleast laterally embedded within the molding compound layer; one or moreintegrated patch antenna structure in the top-side redistribution wiringstructure, wherein the one or more integrated patch antenna structure iscoupled to the RF IC die; an antenna cavity within the molding compoundlayer under each of the one or more integrated patch antenna structure,wherein each of the antenna cavity is defined by a cavity sidewallstructure and one of the at least one or more ground planes, wherein thecavity sidewall structure is provided within the molding compound layerand in electrical contact with the one of the at least one or moreground planes and extending from the one of the at least one or moreground planes through the thickness of the molding compound layer. 12.The integrated fan-out package of claim 11, wherein the cavity sidewallstructure is a single continuous wall structure conductively connectedto the one of the at least one or more ground planes.
 13. The integratedfan-out package of claim 11, wherein the cavity sidewall structurecomprises two or more continuous segments that are conductivelyconnected to the one of the at least one or more ground planes, eachcontinuous segment extending from a corner of the cavity sidewallstructure to an adjacent corner of the cavity sidewall structure. 14.The integrated fan-out package of claim 11, wherein the cavity sidewallstructure comprises a plurality of through-InFO vias that areconductively connected to the one of the at least one or more groundplanes.
 15. The integrated fan-out package of claim 11, wherein themolding compound is one of an epoxy, a polymer, a spin-on-glass, or aceramic.
 16. The integrated fan-out package of claim 11, wherein thetop-side redistribution wiring structure comprises at least three levelsof redistribution wiring layers and the one or more integrated patchantenna structure is provided in a middle one of the at least threelevels of redistribution wiring layers.
 17. The integrated fan-outpackage of claim 11, wherein the one of the at least one or more groundplanes is a solid metal planar structure.
 18. The integrated fan-outpackage of claim 11, wherein the one of the at least one or more groundplanes is formed of a mesh or a set of electrically conductivelyconnected parallel lines.
 19. The integrated fan-out package of claim11, wherein the one or more integrated patch antenna structure comprisesa radiating patch on one side of a dielectric substrate which has aground plane on the other side.
 20. The integrated fan-out package ofclaim 11, wherein each cavity sidewall structure is configured to have aperimeter outline shape that matches the corresponding one or moreintegrated patch antenna structure's perimeter outline.